锻压技术

FCC金属孪晶的EBSD分析

英文标题：Analysis on the twinning of FCC metals by EBSD

作者：陈强强宋广胜徐勇张士宏

关键词：FCC晶体孪晶 EBSD 高温合金

分类号：TG146

出版年,卷(期):页码：2015,40(5):140-144

摘要：

电子背散射衍射技术常采用旋转角/旋转轴的形式来描述晶体中的孪生特征，而一般描述孪生特征的方法是采用孪晶面/孪晶方向的形式。依据孪晶的晶体学原理，推导出了两种描述形式之间的转换方法。针对面心立方金属的4种{111}＜112>孪晶变体，基于上述两种方法获得了4种孪晶变体的两种表达形式，并建立了不同表达形式之间的对应关系。根据该对应关系可知，采用EBSD技术可确定面心立方金属中具体某一变体的孪晶面和孪晶方向。最后，基于EBSD技术的测试结果，采用所得对应关系分析了GH690和GH145两种镍基高温合金的孪晶变体，分析结果表明，４个60°<111>孪晶变体通常在变形中全部启动。

The twinning characteristic of crystal was described by the electron backscatter diffraction (EBSD) technology by the way of rotation angle combined with rotation axis. In general research, it was described by the way of twinning plane combined with twinning direction. Based on crystallographic theory of twinning，the conversion method between the two description ways mentioned above was deduced. For the four {111}<112> twinning variants of face-centered cubic (FCC) metals, two description forms were obtained，and the corresponding relationship between the two description ways was built. The relationship shows that the twinning plane and twinning direction of a specific variant of FCC metals can be determined by EBSD. At last, based on measured results of EBSD, the twinning variants of GH690 and GH145 Ni based superalloys were analyzed by the above relationship. Analysis results show that all the four 60°<111> twin variants usually activate during the deformation.

基金项目：

国家自然科学基金资助项目(50775211, 51174189); 辽宁省教育厅资助项目（L2011024）

陈强强(1988-)，男，硕士研究生宋广胜(1971-)，男，博士，副教授

参考文献：

［1］刘庆. 镁合金塑性变形机理研究进展[J].金属学报, 2010, 46(11):1458-1472.Liu Q. Research progress on plastic deformation mechanism of Mg alloys[J]. Acta Metallurgica Sinica, 2010,46(11):1458-1472.
［2］陈振华，杨春花，黄长清,等.镁合金塑性变形中孪生的研究[J].材料导报,2006,20(8):107-113.Chen Z H, Yang C H, Huang C Q, et al. Investigation of the twinning in plastic deformation of magnesium alloy[J]. Materials Review,2006,20(8):107-113.
［3］Wang L, Yang Y, Eisenlohr P, et al. Twin nucleation by slip transfer across grain boundaries in commercial purity titanium[J]. Metallurgical and Materials Transactions A, 2010, 41(2):421-430.
［4］杨东峰，赵长财，郝海滨. AZ31B镁合金薄板的单向拉伸行为实验研究[J]. 锻压技术, 2012, 37(4): 140-144.Yang D F, Zhao C C, Hao H B. Experimental research on uniaxial tensile behavior of AZ31B magnesium alloy thin sheet[J]. Forging & Stamping Technology, 2012, 37(4): 140-144.
［5］杨俊英，高飞，宁海石，等. 加热温度对AZ31镁合金连续挤压组织与性能的影响[J]. 锻压技术, 2014, 39(5): 106-110.Yang J Y, Gao F, Ning H S, et al. Effect of heating temperature on microstructure and properties of AZ31magnesium alloy in CONFORM process[J]. Forging & Stamping Technology, 2014, 39(5): 106-110.
［6］Christian J W, Mahajan S. Deformation twinning[J].Progress in Materials Science, 1995, 39(1-2):1-157.
［7］刘文西.立方孪晶的复合倒易点阵单胞[J].金属学报, 1978, 14(4):397-408.Liu W X. Composite reciprocal lattice unit cells for cubic twins[J]. Acta Metallurgica Sinica,1978, 14(4):397-408.
［8］Stanford N, Barnet M R. Effect of particles on the formation of deformation twins in a magnesium-based alloy[J]. Materials Science and Engineering A, 2009, 516(1-2):226-234.
［9］Zohreh Keshavarz, Matthew R. EBSD analysis of deformation modes in Mg-3Al-1Zn[J]. Scripta Materialia, 2006, 55(10):915-918.
［10］Bouyne E, Flower H M, Lindley T C. Use of EBSD technique to examine microstructure and cracking in a bainitic steel[J]. Scripta Materialia, 1998, 39: 295-300.
［11］郭可信.面心立方晶体中生成孪晶或六角密堆相的电子衍射分析[J].物理学报,1978,27(5):547-553.Guo K X. Electron diffraction analysis of the twin and hcp phase formed in a FCC crystal[J]. Acta Physica Sinica, 1978,27(5):547-553.
［12］Kocks U F, Tomè C N, Wenk H R. Texture and Anistropy[M]. Cambridge：Cambridge University Press, 1998.
［13］Wu L, Jain A, Brown D W, et al. Twinning-detwinning behavior during the strain-controlled low-cycle fatigue testing of a wrought magnesium alloy, ZK60A[J]. Acta Materialia, 2008, 56(4):688-695.
［14］Myoung-Gyu Lee, R H Wagoner，Lee J K， et al. Constitutive modeling for anisotropic/asymmetric hardening behavior of magnesium alloy sheets[J]. International Journal of Plasticity, 2008, 24(4):545-582.

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